The Effect of Different Dietary Sugars and Honey on Longevity and Fecundity in Two Hyperparasitoid Wasps ⇑ Jeffrey A
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Journal of Insect Physiology 58 (2012) 816–823 Contents lists available at SciVerse ScienceDirect Journal of Insect Physiology journal homepage: www.elsevier.com/locate/jinsphys The effect of different dietary sugars and honey on longevity and fecundity in two hyperparasitoid wasps ⇑ Jeffrey A. Harvey a, , Josianne Cloutier b, Bertanne Visser c, Jacintha Ellers c, Felix L. Wäckers d, Rieta Gols b a Department of Terrestrial Ecology, Netherlands Institute of Ecology, Droevendalsesteeg 10, 6708-PB, Wageningen, The Netherlands b Laboratory of Entomology, Wageningen University, P.O. Box 8031, 6700 EH Wageningen, The Netherlands c Department of Animal Ecology, Institute of Ecological Science, VU University, 1081 HV Amsterdam, The Netherlands d Director Research and Development, Biobest N.V., Ilse Velden 18, B-2260 Westerlo, Belgium article info abstract Article history: In nature adult insects, such as parasitic wasps or ‘parasitoids’ often depend on supplemental nutritional Received 12 January 2012 sources, such as sugars and other carbohydrates, to maximize their life-expectancy and reproductive Received in revised form 5 March 2012 potential. These food resources are commonly obtained from animal secretions or plant exudates, includ- Accepted 5 March 2012 ing honeydew, fruit juices and both floral and extra-floral nectar. In addition to exogenous sources of Available online 31 March 2012 nutrition, adult parasitoids obtain endogenous sources from their hosts through ‘host-feeding’ behavior, whereby blood is imbibed from the host. Resources obtained from the host contain lipids, proteins and Keywords: sugars that are assumed to enhance longevity and/or fecundity. Here we conducted an experiment Cotesia glomerata exploring the effects of naturally occurring sugars on longevity and fecundity in the solitary hyperparasi- Gelis agilis Lysibia nana toids, Lysibia nana and Gelis agilis. Although both species are closely related, L. nana does not host-feed Egg production whereas G. agilis does. In a separate experiment, we compared reproduction and longevity in G. agilis Fecundity reared on either honey, a honey-sugar ‘mimic’, and glucose. Reproductive success and longevity in both Sugar hyperparasitoids varied significantly when fed on different sugars. However, only mannose- and water- Glucose fed wasps performed significantly more poorly than wasps fed on four other sugar types. G. agilis females Longevity fed honey produced twice as many progeny as those reared on the honey-sugar mimic or on glucose, whereas female longevity was only reduced on the mimic mixture. This result shows not only that host feeding influences reproductive success in G. agilis, but also that non-sugar constituents in honey do. The importance of non-sugar nutrients in honey on parasitoid reproduction is discussed. Ó 2012 Elsevier Ltd. All rights reserved. 1. Introduction preferences for feeding on exudates from some species of plants or animals over others. In nature, adult insects often depend on supplemental nutri- In addition to sugars obtained exogenously, some parasitoids tional sources, such as sugars and other carbohydrates, as well as also ‘host-feed’, imbibing blood from the host (Jervis and Kidd, proteins, to maximize their life-expectancy and reproductive po- 1986). Host blood is rich in proteinaceous materials, which are tential. These food resources are commonly obtained from animal important in the manufacture of eggs, whereas proteins are lacking or plant exudates, such as honeydew, fruit juices and both floral in the honeydew and nectar which are generally comprised of car- and extra-floral nectar. In parasitic wasps, or ‘parasitoids’, the ben- bohydrates (Bernstein and Jervis, 2006). Several studies have efits of sugars on fitness-related traits, such as longevity and fecun- shown that resources obtained from host-feeding may be allocated dity, is well established (Jervis et al., 1993; Heimpel et al., 1997; for both reproduction and/or maintenance (Heimpel and Wäckers, 2001; Casas et al., 2003; Lee et al., 2004; Winkler et al., Rosenheim, 1995; Heimpel and Collier, 1996; Giron et al., 2002; 2006; Wäckers et al., 2008; Desouhant et al., 2010; but see Ellers Rivero and West, 2005; Kapranas and Luck, 2008; Zhang et al., et al., 2011). It is also well known that different sugars vary in their 2011). Host blood is often important in the production of large, nutritional quality for parasitoids, with some greatly extending the yolky ‘anhydropic’ eggs (Jervis and Kidd, 1986; Bernstein and lifespan whilst others have little effect or may even be toxic (Jervis Jervis, 2006; Harvey, 2008) that are characteristically produced et al., 1993; Wäckers, 2001; Wäckers et al., 2006; Kehrli and Bach- by many ‘idiobiont’ ectoparasitoids, i.e. parasitoids that attack er, 2008). In the field, therefore, it may pay parasitoids to exhibit non-feeding or non-growing host stages or arrest host develop- ment prior to oviposition (Godfray, 1994; Harvey, 2005; Jervis ⇑ Corresponding author. and Ferns, 2011). In contrast, most endoparasitoids that develop E-mail address: [email protected] (J.A. Harvey). inside the host are ‘koinobionts’ i.e. parasitoids that allow the host 0022-1910/$ - see front matter Ó 2012 Elsevier Ltd. All rights reserved. http://dx.doi.org/10.1016/j.jinsphys.2012.03.002 J.A. Harvey et al. / Journal of Insect Physiology 58 (2012) 816–823 817 to continue feeding and growing during parasitism (Godfray, 1994; Gheldof et al., 2002). Furthermore, honey also contains tiny Harvey, 2005). In koinobionts adult female wasps do not host-feed, amounts of several compounds thought to function as antioxi- and invest very little protein into their tiny ‘hydropic’ eggs. Instead dants, including chrysin, pinobanksin, vitamin C, catalase, and proteins are absorbed from the host blood through a specialized pinocembrin (Martos et al., 2000). extra-embryonic membrane before hatching (Jervis and Kidd, The aims of the study are twofold: first, to determine if longev- 1986; Jervis et al., 2001, 2008). Host blood has also been found ity and fecundity in L. nana and G. agilis are affected when fed on to contain certain sugars, such as trehalose and sucrose that are different naturally occurring sugars; second, to determine if these important in reducing the metabolism of lipids (Giron et al., demographic variables differ in G. agilis when different cohorts 2002). However, this is certainly not the rule, as the longevity of are reared on glucose, honey or a honey-mimic that lacks the trace some parasitoids is not extended at all by host-feeding (Rivero minerals and compounds found in honey. We hypothesize (1) that and West, 2005; Harvey, 2008). Host-feeding parasitoids are gener- longevity and fecundity in these two closely related hyperparasi- ally highly synovigenic, meaning that the adult female wasps toids will be similarly affected by qualitative differences in dietary emerge with few or no ripe eggs and therefore mature most of sugars, and (2) honey provides a high-quality carbohydrate re- their eggs after eclosion (Ellers et al., 2000; Jervis et al., 2001, source affecting longevity similarly as high-quality sugars offered 2008). singly or in a mixture, because sugars and honey are of high value Studies examining life-history variables such as longevity and for maintenance, whereas host-feeding is important for reproduction in parasitoids have rarely integrated the nutritional reproduction. value of different naturally occurring sugars and host-feeding un- der the umbrella of a single ecophysiological framework. Instead, most studies on the nutritional value of different sugars for parasit- 2. Materials and methods oids have explored one demographic character, such as longevity (Wäckers, 2001; Vattala et al., 2006), or else have used non host- 2.1. Insect cultures feeding koinobiont parasitoid species that generally invest very low per capita resources into each egg (Wanner et al., 2006; Win- Lysibia nana and G. agilis have been reared for several years at kler et al., 2006; Faria et al., 2008; Lee and Heimpel, 2008; Wu the Netherlands Institute of Ecology (NIOO) in Heteren, the Nether- et al., 2008). In this way it is impossible to tease apart the benefits, lands. Both hyperparasitoids were originally obtained from co- if any, of different sugars in concert with host feeding, on repro- coons of C. glomerata recovered from leaves of black mustard duction and longevity in parasitoids that require both host- and plants (Brassica nigra) growing adjacent to the NIOO institute. Both non-host resources during adult life to maximize these variables. species were reared according to the protocol described in Harvey A previous study reported that longevity in a primary gregari- (2008). Cultures of L. nana were generated from 200 to 300 C. glom- ous endoparasitoid, Cotesia glomerata L. (Hymenoptera: Braconi- erata cocoons placed in rearing cages with 50 adult L. nana wasps dae), differed significantly when the wasps were fed on 14 for 24 h. Then, parasitized cocoons were transferred to large Petri different sugars that occur naturally (Wäckers, 2001). In this study dishes (18 cm) until adult emergence. The rearing protocol for G. we examine the effects of several naturally occurring sugars found agilis was similar, except that G. agilis had access to a small number in e.g. honeydew and nectar, on longevity and fecundity in two clo- of cocoons for host-feeding purposes 3–4 days before it was pro- sely related species of solitary hyperparasitoids, Lysibia nana vided with new cocoons for oviposition The parasitoids were Gravenhorst and Gelis agilis Fabricius (Hymenoptera: Ichneumoni- reared at 25 ± 2oC with a 16:8 h L:D light:dark regime. Cotesia dae, Cryptinae) that attack the fully cocooned pre-pupae and pupae glomerata was reared on Pieris brassicae L. (Lepidoptera: Pieridae) of C. glomerata in the field. Both species are ectoparasitoids, are caterpillars and was originally collected from agricultural fields wholly synovigenic and produce anhydropic eggs (Harvey, 2008). in the vicinity of Wageningen University. However, they also exhibit several key differences in reproductive and morphological traits. Lysibia nana reproduces sexually and adults are fully winged; by contrast, G.